Effect of Heat Treatment on the Structure of Self-Assembled Undecenyl Phosphonic Acid Layers Developed on Different Stainless Steel Surfaces

IF 0.5 Q4 ENGINEERING, CHEMICAL
Éva Kocsisné Pfeifer, János Mink, I. Gyurika, J. Telegdi
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Abstract

Deterioration caused by corrosion is well known, which can destroy metallic and non-metallic materials alike. Dissolved inhibitors of bionic micro- and nanocoatings can decrease the degree of undesirable corrosion in various ways. In this paper, a self-assembled molecular layer formed from undecenyl phosphonic acid developed on two different steel surfaces was the subject of our experiments. The influence of the metal composition, layer-forming conditions and post-heat treatment was documented by wettability measurements as well as surface roughness parameters; the change in surface morphology caused by the formation of a layer in addition to post-heat treatment was visualized by an atomic force microscope (AFM); and infrared spectroscopy elucidated the bindings of the amphiphilic molecules involved in the self-assembled layer to the metal surface as well as to each other. Over the course of the self-assembling process, the –P(O)(OH)2 head groups can fix the amphiphilic molecule to the solid surface through the metal oxide-hydroxide layer. The hydrophobic alkenyl chains remain together as a result of special forces, namely hydrogen bonds and van der Waals forces, between them. The double bond at the end of the alkenyl chain disturbs how well the layer is ordered. To improve the homogeneity of the molecular layer and increase its level of compactness, the self-assembled molecular (SAM) layer was heat treated to achieve a more compact molecular film that can perfectly cover the metal surface.
热处理对不同不锈钢表面形成的自组装十一烯基膦酸层结构的影响
众所周知,腐蚀造成的性能下降会破坏金属和非金属材料。仿生微涂层和纳米涂层的溶解抑制剂可以通过各种方式降低不良腐蚀的程度。在本文中,我们的实验对象是在两种不同钢材表面形成的由十一烯基膦酸形成的自组装分子层。通过润湿性测量和表面粗糙度参数记录了金属成分、分子层形成条件和后热处理的影响;原子力显微镜(AFM)观察了分子层形成和后热处理引起的表面形态变化;红外光谱分析阐明了自组装分子层中的两亲分子与金属表面以及相互之间的结合情况。在自组装过程中,-P(O)(OH)2 头基可以通过金属氧化物-氢氧化物层将两亲分子固定在固体表面。疏水烯基链由于它们之间的特殊作用力(即氢键和范德华力)而保持在一起。烯基链末端的双键会干扰层的有序性。为了改善分子层的均匀性并提高其致密程度,对自组装分子(SAM)层进行了热处理,以获得更致密的分子膜,使其能够完美地覆盖金属表面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
自引率
50.00%
发文量
9
审稿时长
6 weeks
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